CN219678333U - Thermoelectric generation module structure - Google Patents

Abstract

The utility model relates to a thermoelectric power generation module structure, which comprises a power generation module main body, a fixing frame and a plurality of connecting plates, wherein two wiring terminals are arranged on the surface of the power generation module main body, the fixing frame is arranged on the outer side of the power generation module main body, two supporting columns are arranged on the surface of the fixing frame, a hot air cavity and a cold air cavity are arranged between the inner side of the fixing frame and the power generation module main body, a cold air pipe interface and a hot air pipe interface which are communicated with the hot air cavity and the cold air cavity are respectively arranged on the surface of the fixing frame, two air outlets which are respectively communicated with the hot air cavity and the cold air cavity are respectively arranged on the surface of the fixing frame, a wind collecting frame is arranged on the surface of the fixing frame, a limiting frame is arranged between the power generation module main body and the fixing frame, and the plurality of connecting plates are arranged on the inner side of the fixing frame.

Description

Thermoelectric generation module structure

Technical Field

The utility model relates to the technical field of power generation module structures, in particular to a thermoelectric power generation module structure.

Background

The thermoelectric generation is a solid element manufactured based on the Peltier effect, and the reverse application of the element is generally used as a refrigerating sheet, and the application of the element can be seen in a vehicle-mounted refrigerator, a refrigerating water dispenser and the like.

When utilizing thermoelectric generation module to carry out the electricity generation experiment, need the continuous utilization to carry out temperature difference control to thermoelectric generation module, realize sustainable thermoelectric generation power supply, however, because traditional thermoelectric generation module surface structure is too single, its surface does not design good safeguard measure, when providing high thermoelectric generation wind energy, because can not carry out corresponding processing to high thermoelectric generation wind energy, when the staff is close to, can be because the hot-blast temperature that provides is too high or the condition of unexpected scald or frostbite appears in cold wind temperature too low, there is the potential safety hazard, be unfavorable for on-the-spot staff to carry out the safety experiment.

Disclosure of Invention

Based on the expression, the utility model provides a thermoelectric generation module structure to solve the problem that potential safety hazards exist in outward discharge of high-temperature-difference wind energy.

The technical scheme for solving the technical problems is as follows: the utility model provides a thermoelectric power generation module structure, includes power generation module main part, fixed frame and a plurality of connecting plate, the surface of power generation module main part is equipped with two wiring ends, fixed frame set up in the outside of power generation module main part, the surface of fixed frame be equipped with two support columns, the inboard of fixed frame with be equipped with hot-blast chamber and cold wind chamber between the power generation module main part, the surface of fixed frame is equipped with cold wind pipe interface and the hot-blast pipe interface that are linked together with hot-blast chamber and cold wind chamber respectively, two air outlets that are linked together with hot-blast chamber and cold wind chamber respectively have been seted up on the surface of fixed frame, the surface of fixed frame just be close to offered the position department of air outlet is equipped with gathers the wind frame, the power generation module main part with be equipped with spacing frame between the fixed frame, a plurality of connecting plate set up in the inboard of fixed frame, through be equipped with gather the wind frame corresponding with the air frame of air outlet in the outside, can make outside exhaust hot-blast and between can effectively realize the effect that gathers the reaction mutually, prevent that outside exhaust warm air from excessively high or excessively low and causing the unexpected injury to the work personnel.

On the basis of the technical scheme, the utility model can be improved as follows.

Further, the surface of fixed frame is equipped with a plurality of flexible barrels, the inside of flexible barrel is equipped with the spring, the output of flexible barrel is equipped with the lug, the arc wall has been seted up on the surface of lug and the inboard is equipped with the second silica gel pad, a plurality of the inboard of second silica gel pad respectively with cold air pipe interface with the surface in hot-blast main interface in close contact.

Through telescopic cylinder and the spring that set up, the output of telescopic cylinder sets up lug and second silica gel pad, can effectively realize holding the restriction between relevant pipeline and cold air pipe interface and the hot-blast main interface for it is more stable between relevant pipeline and the corresponding interface.

Further, the surface of support column runs through and has offered the opening, the surface of fixed frame is equipped with a plurality of raised plates, and is a plurality of the surface of flexible section of thick bamboo runs through and has offered the opening, flexible section of thick bamboo is including fixed section of thick bamboo and telescopic link, the surface of flexible section of thick bamboo telescopic link is equipped with the first protruding pole that protrudes to external through the opening, the surface of first protruding pole is connected with the second protruding pole through the axostylus axostyle, the second protruding pole be equipped with be the arch of arc design.

Through the first protruding pole, the second protruding pole and the arch that set up to set up the flange that corresponds at the surface of fixed frame, can realize the effect to the telescopic link restriction of telescopic cylinder, be convenient for the staff will be connected between corresponding pipeline and cold air pipe interface or the hot-blast main interface.

Further, the surface of the convex plate is provided with a concave groove, and the surface of the convex plate is provided with a rubber pad through the concave groove.

Through seting up the indent to set up the rubber pad in the indent, can make the protruding after the adjustment directly contact with between the rubber pad, prevent to be connected between relevant pipeline and the interface that corresponds, the unstable phenomenon of slip appears between its protruding and the boss.

Further, the surface of a plurality of connecting plates is the rectangle and is equipped with first silica gel pad, first silica gel pad keep away from the one side of connecting plate with the surface of spacing frame closely laminates.

Through the design of first silica gel pad, can effectively realize the airtight effect between fixed frame and the power generation module main part, prevent to appear the gas leakage phenomenon in the use.

Further, two third convex rods are arranged on the surface of the second convex rod.

Through the design of two third protruding poles, more be favorable to the staff to adjust second protruding pole and first protruding pole through the third protruding pole.

Further, two handles are arranged on the surface of the fixing frame, and anti-skid patterns are arranged on the surface of the handles.

Through the structural design of handle, the staff of being convenient for carries out the position transfer to this power generation module main part.

Further, a first groove is formed in the surface of the connecting plate, and a second groove is formed in the surface of the connecting plate and close to the position in the first groove.

The staff later stage of being convenient for is dismantled the processing to the connecting plate.

Compared with the prior art, the technical scheme of the utility model has the following beneficial technical effects:

1. through setting up fixed frame in the outside of power generation module main part, and set up the air outlet and set up and gather the wind frame in the outside of fixed frame, can effectually utilize respectively with hot-blast chamber and cold wind chamber be linked together the air outlet and gather the wind frame and realize the effect of gathering to hot and cold wind for can effectively realize the effect of interact between outside exhaust hot-blast and the cold wind, avoid outside exhaust wind temperature too high or too low, thereby can effectively prevent outside exhaust hot-blast or cold wind accident to cause the staff who is close to receive the injury, more be favorable to the staff safe in utilization.

2. Through being equipped with telescopic cylinder, spring, lug and second rubber pad in the outside of fixed frame, can effectively realize realizing the effect of centre gripping restriction to the pipeline that is connected with cold air pipe interface and hot-blast main interface, make the connection between its relevant pipeline and the corresponding interface more temperature, prevent that the problem that the pressurized is easy not hard up exists.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic view of a partial perspective structure of the present utility model;

FIG. 3 is a schematic diagram of the front structure of the present utility model;

FIG. 4 is a schematic view of the internal structure of the telescopic cylinder of the present utility model;

FIG. 5 is a schematic diagram of the position structure of the connecting plate and the first silica gel pad according to the present utility model;

fig. 6 is an enlarged schematic view of the structure of fig. 1 a according to the present utility model.

In the drawings, the list of components represented by the various numbers is as follows:

1. a power generation module body; 11. a terminal; 2. a fixed frame; 21. a handle; 22. an air outlet; 23. a limit frame; 24. a cold air pipe joint; 25. a hot air pipe interface; 26. a support column; 27. a convex plate; 271. a rubber pad; 3. a wind collecting frame; 4. a connecting plate; 41. a first groove; 42. a second groove; 43. a first silicone pad; 5. a telescopic cylinder; 51. a spring; 6. a bump; 61. a second silicone pad; 8. a first protruding rod; 81. a second protruding rod; 82. a third protruding rod; 83. a protrusion.

Detailed Description

In order that the utility model may be readily understood, a more complete description of the utility model will be rendered by reference to the appended drawings. Embodiments of the utility model are illustrated in the accompanying drawings. This utility model may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model.

Referring to fig. 1-5, a thermoelectric power generation module structure comprises a power generation module body 1, a fixing frame 2 and a plurality of connecting plates 4, wherein two terminals 11 are arranged on the surface of the power generation module body 1, two handles 21 are arranged on the surface of the fixing frame 2, anti-skid patterns are arranged on the surface of the handles 21, so that workers can move the power generation module body 1 conveniently, the fixing frame 2 is arranged on the outer side of the power generation module body 1, two support columns 26 are arranged on the surface of the fixing frame 2, a hot air cavity and a cold air cavity are arranged between the inner side of the fixing frame 2 and the power generation module body 1, a cold air pipe interface 24 and a hot air pipe interface 25 which are communicated with the hot air cavity and the cold air cavity are respectively arranged on the surface of the fixing frame 2, two air outlets 22 which are respectively communicated with the hot air cavity and the cold air cavity are arranged on the surface of the fixing frame 2, a wind collecting frame 3 is arranged at a position close to the opened air outlet 22, a limit frame 23 is arranged between the power generation module main body 1 and the fixed frame 2, a plurality of connecting plates 4 are arranged on the inner side of the fixed frame 2, a first groove 41 is formed on the surface of each connecting plate 4, a second groove 42 is formed on the surface of each connecting plate 4 and close to the position in the first groove 41, when power generation experiment operation is required, a worker can move the power generation module main body 1 by using a handle 21, move the power generation module main body 1 to the position to be tested, connect two terminals 11 by using wires, then connect an external hot air blower and an external cold air blower with an air-conditioner by using related air pipes respectively between an air-conditioner pipe interface 24 and an air-conditioner pipe interface 25, then start the hot air blower and the cold air blower, so that related hot air and cold air enter into each cold air chamber of a hot air chamber arranged between the fixed frame 2 and the power generation module main body 1, thereby the top surface and the bottom surface of the power generation module main body 1 surface respectively have high and low temperature, and the effect of thermoelectric power generation is realized.

Referring to fig. 1 to 6, in order to make the connection between the external air duct and the cold air duct interface 24 and the hot air duct interface 25 more warm, preferably, the surface of the support column 26 is perforated with openings, the surface of the fixing frame 2 is provided with a plurality of convex plates 27, the surface of the convex plates 27 is provided with concave grooves, the surface of the convex plates 27 is provided with a rubber pad 271 through the perforated concave grooves, the surface of the fixing frame 2 is provided with a plurality of telescopic cylinders 5, the inside of the telescopic cylinders 5 is provided with springs 51, the output end of the telescopic cylinders 5 is provided with a convex block 6, the surface of the convex block 6 is provided with an arc-shaped groove and the inner side is provided with a second silica gel pad 61, the inner sides of the plurality of the second silica gel pads 61 are respectively in close contact with the surfaces of the cold air duct interface 24 and the hot air duct interface 25, the surfaces of the plurality of telescopic cylinders 5 are perforated with openings, the telescopic cylinders 5 comprise fixing cylinders and telescopic rods, the surfaces of the telescopic cylinders 5 are provided with first convex rods 8 protruding to the outside through the openings, the surface of the first convex rod 8 is connected with a second convex rod 81 through a shaft rod, the surface of the second convex rod 81 is provided with two third convex rods 82, the second convex rod 81 is provided with a convex 83 in arc shape, when the air pipe is connected with the cold air pipe connector 24 and the hot air pipe 25, a worker can utilize the third convex rod 82 to press and pull the second convex rod 81 and the first convex rod 8 outwards, in the pressing and pulling process, the first convex rod 8 drives the telescopic rod of the telescopic cylinder 5 to move simultaneously through a through hole formed in the telescopic cylinder 5, the telescopic rod drives the convex block 6 and the second silica gel pad 61 to move, the spring 51 continuously contracts under the compression of the telescopic rod, the second convex rod 81 is overturned while pressing, the convex 83 of the second convex rod is far away from the convex plate 27 at the corresponding position, the convex 83 of the second convex rod passes over the outer side of the convex plate 27, then the second turned convex rod 81 is turned in the opposite direction, so that the top ends of the protrusions 83 are close to and contacted with the rubber pads 271 through the concave grooves formed in the convex plates 27, the limiting effect on the telescopic rods of the telescopic cylinders 5 is achieved by utilizing the contact between the protrusions 83 and the convex plates 27, and then the corresponding air pipes are connected with the cold air pipe interface 24 and the hot air pipe interface 25.

Referring to fig. 1, 2 and 5, in order to make the tightness between the fixing frame 2 and the power generation module main body 1 better, preferably, the surfaces of the connecting plates 4 are rectangular and provided with a first silica gel pad 43, one surface of the first silica gel pad 43 far away from the connecting plates 4 is tightly attached to the surface of the limiting frame 23, and the surfaces of the connecting plates 4 are provided with the first silica gel pad 43 and tightly contacted with the limiting frame 23, so that the sealing effect between the fixing frame 2 and the power generation module main body 1 is effectively achieved, and the condition that hot air or cold air leaks out in the experimental process is prevented.

The foregoing description of the preferred embodiments of the utility model is not intended to limit the utility model to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the utility model are intended to be included within the scope of the utility model.

Claims (9)

1. The utility model provides a thermoelectric power generation module structure, includes power generation module main part (1), fixed frame (2) and a plurality of connecting plate (4), its characterized in that, the surface of power generation module main part (1) is equipped with two wiring ends (11), fixed frame (2) set up in the outside of power generation module main part (1), the surface of fixed frame (2) is equipped with two support columns (26), the inboard of fixed frame (2) with be equipped with hot-blast chamber and cold wind chamber between power generation module main part (1), the surface of fixed frame (2) be equipped with cold wind pipe interface (24) and hot-blast pipe interface (25) that are linked together with hot-blast chamber and cold wind chamber respectively, the air outlet (22) that are linked together with hot-blast chamber and cold wind chamber respectively are seted up on the surface of fixed frame (2), the surface of fixed frame (2) just be equipped with gather wind frame (3), power generation module main part (1) with be equipped with spacing frame (23) between fixed frame (2), a plurality of connecting plate (4) set up in the inboard of fixed frame (2).

2. The thermoelectric generation module structure according to claim 1, wherein the surface of the fixed frame (2) is provided with a plurality of telescopic cylinders (5), springs (51) are arranged in the telescopic cylinders (5), protruding blocks (6) are arranged at the output ends of the telescopic cylinders (5), arc-shaped grooves are formed in the surfaces of the protruding blocks (6), second silica gel mats (61) are arranged on the inner sides of the protruding blocks, and the inner sides of the second silica gel mats (61) are respectively in tight contact with the surfaces of the cold air pipe interface (24) and the hot air pipe interface (25).

3. The thermoelectric generation module structure according to claim 2, wherein a plurality of protruding plates (27) are arranged on the surface of the fixed frame (2), through holes are formed in the surface of the telescopic cylinder (5), the telescopic cylinder (5) comprises a fixed cylinder and a telescopic rod, a first protruding rod (8) protruding to the outside through the through holes is arranged on the surface of the telescopic rod of the telescopic cylinder (5), a second protruding rod (81) is connected to the surface of the first protruding rod (8) through a shaft rod, and a protrusion (83) in an arc-shaped design is arranged on the surface of the second protruding rod (81).

4. A thermoelectric generation module structure according to claim 3, wherein the surface of the convex plate (27) is provided with a concave groove, and the surface of the convex plate (27) is provided with a rubber pad (271) through the concave groove.

5. A thermoelectric generation module structure according to claim 1, characterized in that the surface of the support column (26) is provided with openings therethrough.

6. The thermoelectric generation module structure according to claim 1, wherein the surfaces of the plurality of connecting plates (4) are rectangular, a first silica gel pad (43) is arranged, and one surface of the first silica gel pad (43) away from the connecting plate (4) is tightly attached to the surface of the limiting frame (23).

7. A thermoelectric generation module structure according to claim 3, characterized in that the surface of the second protruding rod (81) is provided with two third protruding rods (82).

8. The thermoelectric generation module structure according to claim 1, wherein two handles (21) are arranged on the surface of the fixed frame (2), and anti-skidding patterns are arranged on the surface of the handles (21).

9. The thermoelectric generation module structure according to claim 1, wherein a first groove (41) is formed on the surface of the connecting plate (4), and a second groove (42) is formed on the surface of the connecting plate (4) and close to a position in the first groove (41).